1887
1st Australasian Exploration Geoscience Conference – Exploration Innovation Integration
  • ISSN: 2202-0586
  • E-ISSN:
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Abstract

Recent research has shown that Ni-PGE mineralisation is typically associated with specific intrusion types, e.g., chonoliths, bladed-dykes and funnels that acted as high-throughput magma conduits within much larger magmatic provinces. The initial architecture of these systems is very different, but additional structural modification during orogenesis can render such intrusions very difficult to understand structurally, and hence make it very difficult to target the fertile zones within the system. In structural geology it is common to evoke shortening directions, which are assumed to apply to all rocks regardless of their rheology. This is not realistic. Furthermore, resolving the partitioning of strain is not straightforward for intrusive rocks, which tend not to develop visible tectonic fabrics, but act as rigid blocks that rotate to accommodate strain, rather than compress or shear, during deformation. Unfortunately there are few structural techniques that can be used to quantify such rotation.

Intrusions near the Savannah Nickel Mine, East Kimberley, WA were observed to have different deformation histories, despite being temporally equivalent. In this study we measured anisotropy of magnetic susceptibility (AMS) and remanent magnetisation in two adjacent, temporally equivalent, intrusions. The observed K3 AMS vectors are typically normal to the magmatic layering in layered intrusions. Where K3 vectors sit along a great circle, the pole to that great circle indicates the rotation axis. Original palaeomagnetic vectors would be expected to be consistently oriented with respect to magmatic layering, and can be used similarly to test the consistency of the inferred rotation analysis. The rotations inferred for the intrusions tested were consistent between the two techniques. Savannah and Savannah North, were subjected to N-S, NE-SW and NW-SE shortening, consistent with the Halls Creek Orogeny. However, N-S shortening was dominant at Savannah and NE-SW dominant at Savannah North. Therefore, despite their equivalent emplacement ages and implied tectonic history, each intrusion has undergone very different deformation.

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2018-12-01
2026-01-17

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References

  1. Austin, J.R., Barnes, S. J., Godel, B., 2016. Exsolution, fractionation and magnetisation: Links between geophysical expression, architecture, cooling history and PGE prospectivity in the Giles Mafic-Ultramafic Intrusive Complex, Central Australia. 13th International Nickel Symposium 2016, Perth, WA.
  2. Austin, J.R., and Crawford, B., (Submitted). Mapping Remanent Magnetisation as a greenfields exploration tool for Magmatic Ni-Cu-PGE mineralisation: Case study from the Huckitta Area, Arunta Province, NT. Exploration Geophysics.
  3. Barnes, S. J., Cruden, A. R., Arndt, N., and Saumur, B. M., 2015, The mineral system approach applied to magmatic Ni-Cu-PGE sulphide deposits: Ore Geology Reviews.
  4. Griffin, T. J., Tyler, I. M., Orth, K., and Sheppard, S., 1998, Geology of the Angelo 1:100 000 sheet, Geological Series Explanatory Notes: Perth, Geological Survey of Western Australia, p. 27.
  5. Kent, J., Briden, J., and Mardia, K., 1983, Linear and planar structure in ordered multivariate data as applied to progressive demagnetization of palaeomagnetic remanence: Geophysical Journal International, v. 75, p. 593-621.
  6. Le Vaillant, M., Barnes, S. J., Fiorentini, M. L., Mole, D., Austin, J.R., Godel, B., Patterson, B., Hammerli, J., Laflamme, C., Neaud, A., 2017, Magmatic sulphide mineral potential in the East Kimberley: CSIRO Report EP174943.
  7. Lightfoot, P. C., and Evans-Lamswood, D., 2015, Structural controls on the primary distribution of mafic-ultramafic intrusions containing Ni-Cu-Co-(PGE) sulfide mineralization in the roots of large igneous provinces: Ore Geology Reviews, v. 64, p. 354-386.
  8. Orth, K., 2002, Setting of the Palaeoproterozoic Koongie Park Formation and carbonate-associated base metal mineralisation, at Koongie Park, northwestern Australia, University of Tasmania
  9. Saumur, B., Cruden, A., Evans-Lamswood, D., and Lightfoot, P., 2015, Wall-rock structural controls on the genesis of the Voisey’s Bay intrusion and its Ni-Cu-Co magmatic sulfide mineralization (Labrador, Canada): Economic Geology, v. 110, p. 691-711.
  10. Schmidt, P., and Williams, G., 2011, Paleomagnetism of the Pandurra formation and Blue Range Beds, Gawler Craton, South Australia, and the Australian mesoproterozoic apparent polar wander path: Australian Journal of Earth Sciences, v. 58, p. 347-360.
  11. Tyler, I. M., Thorne, A., Sheppard, S., Hoatson, D. M., Griffin, T. J., Blake, D., and Warren, R. G., 1998b, Dixon Range, W.A. Sheet SE 52-6, 1:250 000 Geological Series, Western Australia Geological Survey.
/content/journals/10.1071/ASEG2018abW10_2F
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  • Article Type: Research Article
Keyword(s): Anisotropy of Magnetic Susceptibility (AMS); Layered Intrusive Complex; Nickel-PGE mineralisation; Palaeomagnetic Vectors; Tectonic History

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